Power relay for a vehicle

ABSTRACT

A power relay for a vehicle, in particular a utility vehicle, is disclosed. The power relay contains a housing formed by a connecting base and a housing pot that is placed on the connecting base. Accordingly, two connecting bolts for establishing contact with an on-load circuit are formed by standard screws.

CROSS-REFERENCE TO RELATED APPLICATION

This is a continuation application, under 35 U.S.C. §120, of copendinginternational application No. PCT/EP2015/001031, filed May 21, 2015,which designated the United States; this application also claims thepriority, under 35 U.S.C. §119, of German patent application No. 10 2014007 457.9, filed May 21, 2014; the prior applications are herewithincorporated by reference in their entireties.

BACKGROUND OF THE INVENTION Field of the Invention

The invention relates to a power relay for a vehicle, in particular autility vehicle.

Power relays in accordance with the generic type are used in automotiveengineering, in particular for utility vehicles. In this case, the powerrelays are used on the one hand so as to electrically separate thevehicle battery from the on-board power system. On the other hand, suchrelays are used so as to connect electric motors of adjusting devices(for example a hydraulic pump or lifting platform). In the case of a lowvoltage of typically 12 to 24 volt, such a power relay must be able toswitch currents up to a current strength of approximately 300 ampere andmust be of an accordingly robust construction. Relays usually used forthis purpose are generally embodied from a pot-shaped body of metal (forexample iron or steel) in which are accommodated a magnetic core, amagnetic yoke and a magnetic armature that is connected to a contactbridge (double contact).

In order to connect the power relay to a load current circuit that is tobe switched in the vehicle, the power relay generally contains solidconnection bolts (threaded bolts) that are embodied from metal andtypically have a diameter of 0.5 to 1 cm. These connection bolts atwhich in the proper manner cable lugs of the connection lines of theload current circuit that is to be connected are defined in a contactingmanner by screw nuts (contact nuts) are generally formed by specialturned parts that are comparatively complex and consequently expensiveto produce.

Power relays of the above described type are known in particular frompublished, non-prosecuted Germen patent applications DE 10 2010 018 755A1 (corresponding to U.S. patent publication No. 2011/0267158), DE 102010 018 738 (corresponding to U.S. patent publication No.2011/0267157)A1, DE 39 33 493 A1 (corresponding to U.S. Pat. No.4,969,844) and U.S. Pat. No. 4,595,811.

German utility model DE 90 01 337 U1 discloses a further power relay inwhich the connection bolts are formed in each case by a screw having ahexagonal screw head. The screws are inserted from the housing interiorinto the through-going apertures of a housing socket so that each of thescrews protrude outwards with their threaded shaft through the housingsocket, whereas the hexagonal head lies in a corresponding receivingarrangement of the housing socket.

SUMMARY OF THE INVENTION

The object of the invention is to provide a power relay that can beproduced in a particularly rational manner for a vehicle, in particulara utility vehicle.

This object is achieved in accordance with the invention by means of thefeatures of the main claim. The power relay in accordance with theinvention contains a housing that is formed from a connection socket anda housing pot that is placed thereon. Two connection bolts are insertedinto the housing socket and by way of the connection bolts contact canbe made between the power relay and the connection lines of an externalload current circuit that is to be connected. In accordance with theinvention, the connection bolts are formed by standard screws, inparticular in accordance with ISO 4014 (or DIN 931-1) or ISO 4017 (orDIN 933). As is generally the case with screws, each connection boltcontains a threaded shaft—which is to be provided with a metalthread—and a screw head that is wider with respect to said connectionbolt.

By virtue of using standard screws as the connection bolts, theproduction outlay and the production costs for the power relay areconsiderably reduced. Standard screws are commercially available asmass-produced items.

In order to be able to tighten the contact nuts in a simple manner asthey make contact with the load current circuit, the respective screwhead of the connection bolts preferably contains a non-circular outercontour. In particular, the screw head is formed in this case as ahexagonal head. The non-circular screw head holds the respectiveconnection bolt in a non-rotatable manner in the connection socket byforming a form-locking connection with the connection socket. Aform-locking connection is a connection based on the shape of the partsinteracting with each other (e.g. a ball and socket).

In accordance with the invention, the connection bolts having therespective screw head lie loosely in a respective correspondingreceiving arrangement of the connection socket. The term “loosely” isunderstood in this case to mean to such an extent that the connectionbolts are not directly connected to the material of the connectionsocket. The connection bolts can as a result move slightly in particularwith respect to the connection socket.

Each of the connection bolts is held in an expedient embodiment by aconnecting conductor that is preferably formed by a bent sheet metalstamped part. Each of the connecting conductors is fixed in theconnection socket and encompasses the outer face of the screw head sothat the respective connection bolt is held in a loss-proof manner inthe connection socket. The connecting conductors are used simultaneouslyto conduct the load current into the housing inner space.

In order to hold the respectively allocated connection bolt in theconnection socket, each of the connecting conductors contains in anexpedient construction a bore hole in a central section and theallocated connection bolt is guided with its threaded shaft through saidbore hole. Each of the connecting conductors contains in an expedientmanner on both sides of this central section in each case a fixing limbthat is bent at 90° in particular with respect to the central section.The connecting conductor is fixed by the fixing limbs in the connectionsocket. In terms of a particularly simple process of producing the powerrelay, each of the connecting conductors is pressed by the fixing limbsin particular into the connection socket.

In a simple but simultaneously expedient embodiment, each connectingconductor also forms a fixed contact of the (main) switching device thatis formed within the power relay for switching the load current circuit.For this purpose, one contact end is formed on at least one of thefixing limbs of each connecting conductor and the respective connectingconductor protrudes with the contact end into the housing inner space.The contact end supports a contact element of the switching device. Itis preferred that in each case both fixing limbs of the connectingconductor is provided with contact ends that protrude into the housinginner space and support in each case a contact element. Consequently,each fixed contact is formed in a redundant manner by two parallelswitched part contacts. In cooperation with a contact bridge, whichforms the movable contact of the main switching device and in a closedposition bridges the fixed contacts in an electrically conductive mannerso as to close the load current circuit, a four-point contact isconsequently produced in which the load current circuit is closed by wayof a series connection of two respectively parallel connected contactpoint pairs. In comparison to a conventional two-point contact in whichboth fixed contacts are formed in each case only in a simple manner, areduced transition resistance is achieved by this four-point contact inthe through-connected (electrically conductive) state of the powerrelay.

It is preferred that each of the two contact ends of each connectingconductor is bent away from the adjacent fixing limb in such a mannerthat the contact elements that are arranged in each case on the contactends are orientated in an inclined manner with respect to the housingaxis. The mutually opposite contact elements of the fixed contacts areas a consequence in particular facing one another in an inclined manner.The inclined contact ends of the connecting conductors thus correspondto a contact bridge that is formed bent in the shape of the letter V orcontains bridge ends that are at least bent in an inclined manner. Theinclined position of the contact ends ensures that the contact elementsof all four contact ends make contact with corresponding mating contactelements of the contact bridge.

In one expedient embodiment variant, the two contact ends of eachconnecting conductor are bent in each case towards one another. With thecentral section, the fixing limbs that are bent away from the centralsection, and the contact ends that are in turn bent with respect to thefixing limbs, each connecting conductor thus contains in simplifiedmanner the shape of a frame that is slotted on one side and encompassesa spatial volume on four sides.

In order on the one hand to be able to insert, in particular press in,the connecting conductor that is configured in this manner into theconnection socket, but in order on the other hand to prevent a hollowspace, which would otherwise impair the stability of the power relay,from remaining within the connection socket, a filler element isallocated in an advantageous embodiment to each connecting conductor,wherein the filler element is embodied as a separate part from theconnection socket and completely fills or at least fills around the edgeof the volume that is encompassed by the connecting conductor. Thefiller element is used in this case in particular also so as tostabilize the allocated connecting conductor. It is preferred that thefiller element is inserted into the respective connecting conductorduring the production of the power relay. The component that is formedby the connecting conductor and the filler element is then pressed intothe connection socket—after the allocated connection bolt has beeninserted.

The connection socket is preferably a component that is injection moldedfrom a synthetic material.

Other features which are considered as characteristic for the inventionare set forth in the appended claims.

Although the invention is illustrated and described herein as embodiedin a power relay for a vehicle, it is nevertheless not intended to belimited to the details shown, since various modifications and structuralchanges may be made therein without departing from the spirit of theinvention and within the scope and range of equivalents of the claims.

The construction and method of operation of the invention, however,together with additional objects and advantages thereof will be bestunderstood from the following description of specific embodiments whenread in connection with the accompanying drawings.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING

FIG. 1 is a perspective oblique view from above of a power relay for aheavy goods vehicle according to the invention;

FIG. 2 is an exploded, perspective view of four sub-assemblies of thepower relay, namely a connection socket, a housing pot, a coil assemblyand a circuit board that supports an electronic control system;

FIG. 3 is an exploded perspective view of the connection socket of thepower relay and also two connection bolts having in each case anallocated connecting conductor, a respectively allocated filler elementand a respectively allocated auxiliary conductor;

FIGS. 4 and 5 are perspective views of one of the connecting conductorsas seen from two different directions;

FIG. 6 is a diagrammatic, perspective view of a procedure of assemblingone of the connection bolts with the filler element, the connectingconductor and the auxiliary conductor;

FIG. 7 is a perspective view of a procedure of assembling the connectionsocket with an assembly unit that is formed from the connection bolt,the filler element, the connecting conductor and the auxiliaryconductor;

FIG. 8 is a perspective oblique view from above of an assembledconnection socket;

FIG. 9 is a perspective oblique view from below of a finished assembledconnection socket; and

FIG. 10 is a cross-sectional view taken along the line X-X shown in FIG.1 of the mounted power relay.

DETAILED DESCRIPTION OF THE INVENTION

Mutually corresponding parts are always provided in all figures withlike reference numerals.

Referring now to the figures of the drawings in detail and first,particularly to FIG. 1 thereof, there is shown a power relay 1 that isillustrated as a complete unit in FIG. 1. The power relay contains ahousing 2 that is formed from two parts, namely a connection socket 3and a housing pot 4. Both the connection socket 3 and also the housingpot 4 are formed in this case as components that are injection moldedfrom a synthetic material.

The connection socket 3 delimits the housing 2 with respect to aconnection face and the power relay 1 can be connected on a connectionface to an external load current circuit. This connection side issubsequently also referred to as the upper face 5—irrespective of theactual orientation of the power relay 1 in the surrounding space. Thehousing pot 4 encompasses with four side walls 6 and a housing base 7the remaining faces of an approximately cuboid-shaped housing innerspace 8 (see FIG. 10). In so doing, the housing base 7 closes thehousing 2 with respect to a lower face 9 that is remote from the upperface 5, (wherein also the term “lower face” is used irrespective of theactual orientation of the power relay 1 in the surrounding space).

In order to connect two connection lines of the load current circuitthat is to be connected, two solid connection bolts 10 are fixed in theconnection socket 3 and the connection bolts protrude with a threadedshaft 11 outwards in each case from the housing 2. In order to connectthe respective connection line of the load current circuit, an end-facecable lug of this connection line is placed on the allocated threadedshaft 11 and is contacted by the thread of a screw nut (contact nut).

In order to prevent an electrical flashover or any other short circuitbetween the connection bolt 10 and the connection lines of the loadcurrent circuit that are possibly fastened thereto, a partition wall 12is formed on the outer face of the connection socket 3 and the partitionwall protrudes into the intermediate space that is formed between theconnection bolts 10.

In order to control the power relay 1, in other words to initiate theswitching processes by which the power relay 1 is to be switched in—byvirtue of producing inside the housing an electrically conductiveconnection between the connection bolts 10—or to be switched out—byvirtue of separating this electrically conductive connection, multipleconnections 13 are formed on the housing pot 4 and correspondingexternal signal lines can be connected in a clamped manner to the powerrelay 1 by way of the multiple signal connections. The signal lines areused so as to direct at least one electrical control signal to the powerrelay 1 and/or so as to output at least one electrical state signal bythe power relay 1. As an option, at least one of the signal connections13 is also provided so as to supply an electrical supply voltage, inparticular ground. The signal connections 13 are embodied as contacts ofa plug connector 14 that is formed as one piece on the wall of thehousing pot 4.

FIG. 2 illustrates the power relay 1 in a partly disassembled state. Itis evident in this illustration that the power relay 1 is formed fromfour assemblies that are associated with one another. In addition to thealready described housing parts, namely the connection socket 3 with theconnection bolts 10 attached thereto and also in addition to the housingpot 4 with the plug connector 14 formed as one thereon, the power relay1 contains accordingly a coil assembly 20 and also a line carrier thatis referred to hereinunder as a circuit board 21.

The coil assembly 20 contains a contact bridge 22 that is mechanicallycoupled by way of a coupling rod 23 to a magnetic armature 24 of amagnetic circuit, the magnetic armature being bent in the interior ofthe coil assembly 20 and only visible in FIG. 10. In addition to themagnetic armature 24, the magnetic circuit contains a magnetic yoke 25,wherein this magnetic yoke 25 is formed by a central, hollow-cylindricalcore 26 that surrounds the coupling rod 23 in a concentric manner, aU-shaped bent bracket 27 and also two pole shoes 28 that extend towardsone another from the limb ends of the bracket (FIG. 10). In so doing,the pole shoes 28 enclose the magnetic armature 24 between one another.The magnetic armature 24 and the components of the magnetic yoke 15 areformed from a ferromagnetic material.

The power relay 1 can be embodied in particular as a bi-stable relay. Inthis case, in each case one or multiple permanent magnets are arrangedbetween the pole shoes 28 and the limb ends of the bracket 27. In thecase of mono-stable variants of the power relay 1, the permanent magnetsare replaced by a ferromagnetic material.

The coil assembly 20 contains furthermore a magnetic coil 29 that liesin the volume that is framed by the magnetic yoke 25. The magnetic coil29 surrounds the core 26 of the magnetic yoke 25 in a concentric mannerand for its part is framed by the bracket 27 and the pole shoes 28.

The circuit board 21 is formed from two sections 30 and 31 that areconnected to one another in an articulated manner by way of a film hinge32 and can therefore be bent out of an original planar state into theL-shaped arrangement that is illustrated in FIG. 2. In the case of theillustrated electronic construction of the power relay 1, the section 30supports the electronic control system 33. The section 31 containsmainly contact sites so as to make electrical contact with the magneticcoil 29 and also so as to make contact with electrical functioningelements that are provided as an option so as to discharge the coils,display the switching position, overtemperature shut-down, etc.

As an alternative to the illustrated electronic construction of thepower relay 1, purely electromechanical constructions of the power relay1 are provided. In the case of these constructions, the circuit board 21is preferably likewise provided. However, in this case, the circuitboard does not support an electronic control system 33 but rather itonly supports conductor tracks so as to connect the magnetic coil 29 andthe possibly provided electrical functioning elements to the signalconnections 13. As an alternative, the circuit board 21 is replaced bywire conductors in the case of purely electromechanical constructions ofthe power relay 1.

FIG. 3 illustrates an exploded view of the connection socket 3 with theconnection bolts 10 and further components of the power relay 1 that inthe proper assembled state of the power relay 1 are fixed to theconnection socket 3. It is evident from the illustration that each ofthe two connection bolts 10 is formed by a standard screw having ahexagonal head 40. The connection bolts 10 are in this case inparticular standard screws in accordance with ISO 4017, wherein thethreaded shaft 11 is provided in each case with a metric thread (inparticular M6, M8, M10 or M12) that extends as far as the hexagonal head40. Each connection bolt 10 is allocated in each case a connectingconductor 41, a filler piece 42 and also an auxiliary conductor 43.

The auxiliary conductor 41 is used in this case to provide an electricalcontact between the allocated connection bolt 10 and the housing innerspace 8. As is particularly evident in FIGS. 4 and 5, that illustrateone of the connecting conductors 41 individually, each of the connectingconductors 41 is formed by a bent sheet metal stamped part. Each of theconnecting conductors 41 contains a central section 50 that is formed inthe shape of a bracket and is provided with a central bore hole 51 so asto receive the threaded shaft 11 of the allocated connection bolt 10.The two opposite-lying side edges of the central section 50 become ineach case a fixing limb 52. The two fixing limbs 52 are used so as tofix the respective connecting conductor 41 in the connection socket 3.The fixing limbs 52 are bent in each case at an approximate right angleaway from the central section 50 and are provided on their side edgeswith a respective saw-toothed contour 53. The ends of the two fixinglimbs 52 of each connecting conductor 41, the ends being remote from thecentral section 50, are in turn bent by approximately 90° with respectto one another so that the connecting conductor 41 contains almost theshape of a frame or ring that is slotted on one side. The bent ends ofthe fixing limbs 52 are described hereinunder as the contact ends 54.Each contact end 54 supports a contact element 55 that is pressed in.

The filler pieces 42 are components that are injection molded. Eachfiller piece 42 is shaped on an outer face 56 in such a manner that itcan be inserted with this outer face 56 in such a manner that it fitsprecisely into the volume that is encased by the associated connectingconductor 41. On an inner face 57 that lies opposite the outer face 56,a receiving arrangement 58 is formed in each of the two filler pieces 42and so as to produce a form closure the hexagonal head 40 of theassociated connection bolt 10 can be inserted into the receivingarrangement in such a manner that it fits precisely or with a smallamount of play with slightly half of its circumference.

The auxiliary conductors 43 are bent sheet metal stamped parts thatextend lengthwise.

FIGS. 6 and 7 illustrate schematically the procedure of assembling theconnection bolt 10, the connecting conductor 41, the filler element 42and the auxiliary conductor 43 in the connection socket 3. As indicated,initially in each case one of the auxiliary conductors 43 is welded orriveted on the inner face (in other words on the face that lies oppositeto the contact element 55) to one of the contact ends 54 of an allocatedconnecting conductor 41. Furthermore, in each case one of the connectionbolts 10 having the hexagonal head 40 is inserted into the receivingarrangement 48 of the associated filler piece 42. Subsequently, theconnecting conductor 41 with the auxiliary conductor 43 that is solderedon in accordance with FIG. 6 is slid onto the connection bolt 10 so thatthe connection bolt 10 having the threaded shaft 11 protrudes throughthe bore hole 51 of the connecting conductor 41, and that the connectingconductor 41 having the fixing limbs 52 and its contact ends 54encompasses the filler piece 42. The assembly unit that is formed inthis manner from the respective connection bolt 10, the associatedconnecting conductor 41, the filler piece 42 and the auxiliary conductor43 is subsequently pressed from above into a corresponding receivingarrangement 59 of the housing pot 4 in accordance with FIG. 7, whereinthe saw-toothed contours 53 that are provided on the fixing limbs 52hook into the material of the housing pot 4.

FIGS. 8 and 9 illustrate the connection socket 3 in a finished assembledstate. In this state, the connection bolts 10 having their hexagonalhead 40 are received in each case in a positive-locking manner and anon-rotatable manner in the connection socket 3 so that the threadedshaft 11 of the connection bolts 10 protrudes in each case towards theupper face 5 outwards towards the connection socket 3. The connectionbolts 10 are received loosely in the connection socket 3 andconsequently are not connected to the material of the connection socket3. In particular, the connection bolts 10 can also move slightly withrespect to the connection socket 3. The connection bolts 10 are securedto prevent loss in this case only by means of the respective associatedconnecting conductor 41 that encompasses the outer face of the hexagonalhead 40 with the central section 50.

In accordance with FIG. 9, the connecting conductors 41 protrude withtheir respective contact ends 54 at a lower face of the housing socket 3into the housing inner space 8. The contact elements 55 that areattached in each case to the contact ends 54 thus form the fixedcontacts of a main switching device of the power relay 1, the mainswitching device being provided so as to switch the load currentcircuit. The corresponding movable contact of this main switching deviceis formed by the contact bridge 22 of the coil assembly 20 that containsa mating contact element 60 (FIG. 2) that corresponds for this purposeto each contact element 55 of the connecting conductor 41.

In order to mount the power relay 1, the coil assembly 20 is clippedfrom below onto the previously assembled connection socket 3. For thispurpose, the connection socket 3 is provided on its lower face withinjection-molded snap-in hooks 61 (FIG. 2) that grip on both sides belowthe bracket 27 of the magnetic yoke 25.

The circuit board 21 is mounted after, prior to or simultaneously withclipping on the coil assembly 20. In particular, the auxiliaryconductors 43 and the coil connections (not explicitly illustrated) ofthe magnetic coil 29 are soldered to the corresponding contact sites onthe section 31 of the circuit board 21. Subsequently, the housing pot 4is placed over the coil assembly 20 and the circuit board 21 and screwedto the connection socket 3, as a consequence of which the housing 2 isclosed. In order to seal the housing 2, a casting compound 65 (FIGS. 1and 10) is poured over the connection between the connection socket 3and the housing pot 4.

As is evident in FIG. 10, in the finished assembled state of the powerrelay 1, the contact elements 55 of the connecting conductor 41 lie ineach case opposite to a mating contact element 60 of the contact bridge22. The mating contact elements 60 are electrically short circuitedwithin the contact bridge 22. It is furthermore evident in FIG. 10 thatthe contact ends 54 of the connecting conductor 41 are bent away fromthe respective adjacent fixing limb 52 in such a manner that they areinclined with respect to the respective associated central section 50,and consequently are also arranged in an inclined manner with respect toa housing axis 66 of the power relay 1. Taken together, the contact ends54 thus form a saddleback roof-type structure. The contact elements 55that are attached to the face of the contact ends 54 that is facing thehousing inner space 8 are as a consequence facing one another in aninclined manner.

So as to match the arrangement of the contact elements 55, the contactbridge 22 also contains a V-shaped or roof-shaped structure with endsthat are bent in an inclined manner so that the mating contact elements60 are arranged parallel to the corresponding contact elements 55. Theinclined position of the contact elements 55 and the correspondingmating contact elements 60 facilitates in this manner a good contactconnection of all four contact elements 55 with the corresponding matingcontact elements 60.

FIG. 10 illustrates the power relay 1 in an open position in which themating contact elements 60 are raised from the contact elements 55 (inother words the contact is broken) so that the connection bolts 10 arenot connected in an electrically conductive manner. The magnetic coil 29is energized so as to switch on the power relay 1. As a consequence, amagnetic flux is generated in the magnetic yoke 25 by which the magneticarmature 24 is drawn against the core 26 of the magnetic yoke 25. Themagnetic armature 24 is used together with the coupling rod 23 todeflect the contact bridge 22 upwards so that the mating contactelements 60 abut against the corresponding contact elements 55. Aconductive connection between the connecting bolts 10 is formed by wayof the contact bridge 22 when the power relay 1 is in the closedposition that is produced in this manner.

In order to switch off the power relay 1, the magnetic coil 29 isenergized with the reversed polarity. Under the influence of themagnetic flux that is generated in the magnetic yoke 25, the holdingforce that is generated by the permanent magnets 29 is compensated for,as a result of which the magnetic armature 24 is separated from the core26 by a restoring spring 67 (FIG. 10) and consequently pushed into theopen position in accordance with FIG. 10. In so doing, the magneticarmature 24 entrains in turn the contract bridge 22 by way of thecoupling rod 23, as a consequence of which—by separating the electricalconnection between the connection bolts 10—the contact between themating contact elements 60 and the corresponding contact elements 55 isbroken.

In the illustrated bi-stable construction of the power relay 1, each ofthe two switching positions of the power relay 1 is also stable in thenon-energized state of the magnetic coil 29. In this case, it is onlynecessary to energize the magnetic coil 29 temporarily.

A supply voltage for the electronic control system 33 is supplied to thecircuit board 21 by way of the auxiliary conductor 43. Furthermore, whenthe power relay 1 is in the switched-on state, the electronic controlsystem 33 uses the potential that is tapped by way of the auxiliaryconductor 43 to ascertain the voltage that is dropping between theconnection bolts 10 as a measurement for the current strength of theload current that is flowing through the power relay 1 in order toautomatically switch off the power relay 1 in the event of an overloador short circuit.

The invention is particularly clarified with reference to the abovedescribed exemplary embodiment but nonetheless is not limited to thisexemplary embodiment. On the contrary, numerous further embodiments ofthe invention can be derived from the claims and the above description.

The following is a summary list of reference numerals and thecorresponding structure used in the above description of the invention:

-   1 Power relay-   2 Housing-   3 Connection socket-   4 Housing pot-   5 Upper face-   6 Side wall-   7 Housing base-   8 Housing inner space-   9 Lower face-   10 Connection bolt-   11 Threaded shaft-   12 Partition wall-   13 Signal connection-   14 Plug connector-   20 Coil assembly-   21 Circuit board-   22 Contact bridge-   23 Coupling rod-   24 Magnetic armature-   25 Magnetic yoke-   26 Core-   27 Bracket-   28 Pole shoe-   29 Magnetic coil-   30 Section-   31 Section-   32 Film hinge-   33 Electronic control system-   40 Hexagonal head-   41 Connecting conductor-   42 Filler piece-   43 Auxiliary conductor-   50 Central section-   51 Bore hole-   52 Fixing limb-   53 Saw-toothed contour-   54 Contact end-   55 Contact element-   56 Outer face-   57 Inner face-   58 Receiving arrangement-   59 Receiving arrangement-   60 Mating contact element-   61 Snap-in hooks-   65 Casting compound-   66 Housing axis-   67 Restoring spring

1. A power relay for a vehicle, the power relay comprising: a housingformed from a connection socket and a housing pot that is disposed onsaid connection socket, said connection socket having a receivingarrangement and connecting conductors; and two connection bolts insertedinto said connection socket so as to make contact with a load currentcircuit, said connection bolts each having a screw with a threaded shaftand a screw head, each of said connection bolts having said screw headdisposed loosely in said receiving arrangement of said connection socketso that said threaded shaft protrudes outwards from said connectionsocket, each said screw head is encompassed on an outer face by one ofsaid connecting conductors of said connection socket and consequently isheld in a secure manner in said receiving arrangement.
 2. The powerrelay according to claim 1, wherein said screw head of each of saidconnection bolts has a non-circular outer contour.
 3. The power relayaccording to claim 1, wherein: each of said connecting conductors has abore hole formed therein in a central section and each of saidconnection bolts having said threaded shaft is guided through said borehole; and each of said connecting conductors have two fixing limbs withone of said fixing limbs disposed on each side of said central section,said fixing limbs are fixed in said connection socket.
 4. The powerrelay according to claim 3, wherein each of said connecting conductorshaving said fixing limbs is pressed into said connection socket.
 5. Thepower relay according to claim 3, wherein: in each case said two fixinglimbs of each of said connecting conductors protrude with a contact endinto a housing inner space that is enclosed by said housing; and eachsaid contact end has in each case a contact element of a switchingdevice for switching the load current circuit.
 6. The power relayaccording to claim 5, wherein said contact end of each of saidconnecting conductors is disposed in an inclined manner with respect tosaid central section so that said contact element that is disposed ineach case on said contact end is disposed in an inclined manner withrespect to a housing axis.
 7. The power relay according to claim 5,wherein said contact end of each of said connecting conductors is ineach case bent towards one another.
 8. The power relay according toclaim 7, further comprising filler elements, each of said connectingconductors is allocated one of said filler elements that is separatefrom said connection socket and that completely fills or at leastsurrounds at least around an edge of a volume that is encompassed bysaid connecting conductor.
 9. The power relay according to claim 1,wherein said connection socket is embodied as a component that isinjection molded from a synthetic material.
 10. The power relayaccording to claim 1, wherein said screw head of each of said connectionbolts has a hexagonal outer contour.